LINQ to DB is the fastest LINQ database access library offering a simple, light, fast, and type-safe layer between your POCO objects and your database.
Architecturally it is one step above micro-ORMs like Dapper, Massive, or PetaPoco, in that you work with LINQ expressions, not with magic strings, while maintaining a thin abstraction layer between your code and the database. Your queries are checked by the C# compiler and allow for easy refactoring.
However, it's not as heavy as LINQ to SQL or Entity Framework. There is no change-tracking, so you have to manage that yourself, but on the positive side you get more control and faster access to your data.
In other words LINQ to DB is type-safe SQL.
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- Rich Querying API:
- Explicit Join Syntax (In addition to standard LINQ join syntax)
- CTE Support
- Bulk Copy/Insert
- Window/Analytic Functions
- Merge API
- Extensibility:
See Github.io documentation for more details.
Code examples and demos can be found here or in tests.
Release notes page.
- linq2db.EntityFrameworkCore (adds support for linq2db functionality in EF.Core projects)
- LinqToDB.Identity - ASP.NET Core Identity provider using Linq To DB
- LINQPad Driver
- DB2 iSeries Provider
- ASP.NET CORE 2 Template
- ASP.NET CORE 3 Template with Angular
- ASP.NET CORE 5 Template
- PostGIS extensions for linq2db
Notable open-source users:
- nopCommerce - popular open-source e-commerce solution
- OdataToEntity - library to create OData service from database context
- SunEngine - site, blog and forum engine
Unmantained projects:
- IdentityServer4.LinqToDB - IdentityServer4 persistence layer using Linq To DB
You can simply pass connection string into DataConnection
or DataContext
constructor using DataOptions
class.
Minimal configuration example:
var db = new DataConnection(
new DataOptions()
.UseSqlServer(@"Server=.\;Database=Northwind;Trusted_Connection=True;"));
Use connection configuration action to setup SqlClient-specific authentication token:
var options = new DataOptions()
.UseSqlServer(connectionString, SqlServerVersion.v2017, SqlServerProvider.MicrosoftDataSqlClient)
.UseBeforeConnectionOpened(cn =>
{
((SqlConnection)cn).AccessToken = accessToken;
});
// pass configured options to data context constructor
var dc = new DataContext(options);
Tip
There are a lot of configuration methods on DataOptions
you can use.
[!TIP]
It is recommended to create configured DataOptions
instance once and use it everywhere. E.g. you can register it in your DI container.
In your web.config
or app.config
make sure you have a connection string (check this file for supported providers):
<connectionStrings>
<add name="Northwind"
connectionString = "Server=.\;Database=Northwind;Trusted_Connection=True;"
providerName = "SqlServer" />
</connectionStrings>
Alternatively, you can implement custom settings provider with ILinqToDBSettings
interface, for example:
public class ConnectionStringSettings : IConnectionStringSettings
{
public string ConnectionString { get; set; }
public string Name { get; set; }
public string ProviderName { get; set; }
public bool IsGlobal => false;
}
public class MySettings : ILinqToDBSettings
{
public IEnumerable<IDataProviderSettings> DataProviders
=> Enumerable.Empty<IDataProviderSettings>();
public string DefaultConfiguration => "SqlServer";
public string DefaultDataProvider => "SqlServer";
public IEnumerable<IConnectionStringSettings> ConnectionStrings
{
get
{
// note that you can return multiple ConnectionStringSettings instances here
yield return
new ConnectionStringSettings
{
Name = "Northwind",
ProviderName = ProviderName.SqlServer,
ConnectionString =
@"Server=.\;Database=Northwind;Trusted_Connection=True;"
};
}
}
}
And later just set on program startup before the first query is done (Startup.cs for example):
DataConnection.DefaultSettings = new MySettings();
See article.
You can generate POCO classes from your database using linq2db.cli dotnet tool
.
Alternatively, you can write them manually and map to database using mapping attributes or fluent mapping configuration
. Also you can use POCO classes as-is without additional mappings if they use same naming for classes and properties as table and column names in database.
using System;
using LinqToDB.Mapping;
[Table("Products")]
public class Product
{
[PrimaryKey, Identity]
public int ProductID { get; set; }
[Column("ProductName"), NotNull]
public string Name { get; set; }
[Column]
public int VendorID { get; set; }
[Association(ThisKey = nameof(VendorID), OtherKey=nameof(Vendor.ID))]
public Vendor Vendor { get; set; }
// ... other columns ...
}
This approach involves attributes on all properties that should be mapped. This way lets you to configure all possible things linq2db ever supports. There is one thing to mention: if you add at least one attribute into POCO, all other properties should also have attributes, otherwise they will be ignored:
using System;
using LinqToDB.Mapping;
[Table("Products")]
public class Product
{
[PrimaryKey, Identity]
public int ProductID { get; set; }
// Property `Name` will be ignored as it lacks `Column` attibute.
public string Name { get; set; }
}
This method lets you configure your mapping dynamically at runtime. Furthermore, it lets you to have several different configurations if you need so. You will get all configuration abilities available with attribute configuration. These two approaches are interchangeable in their abilities. This kind of configuration is done through the class MappingSchema
.
With Fluent approach you can configure only things that require it explicitly. All other properties will be inferred by linq2db:
// IMPORTANT: configure mapping schema instance only once
// and use it with all your connections that need those mappings
// Never create new mapping schema for each connection as
// it will seriously harm performance
var myFluentMappings = new MappingSchema();
var builder = mappingSchema.GetFluentMappingBuilder();
builder.Entity<Product>()
.HasTableName("Products")
.HasSchemaName("dbo")
.HasIdentity(x => x.ProductID)
.HasPrimaryKey(x => x.ProductID)
.Ignore(x => x.SomeNonDbProperty)
.Property(x => x.TimeStamp)
.HasSkipOnInsert()
.HasSkipOnUpdate()
.Association(x => x.Vendor, x => x.VendorID, x => x.VendorID, canBeNull: false)
;
//... other mapping configurations
// commit configured mappings to mapping schema
builder.Build();
In this example we configured only three properties and one association. We let Linq To DB to infer all other properties as columns with same name as property.
To use your MappingSchema
instance you should pass it DataConnection
or DataContext
constructor:
var options = new DataOptions()
.UseSqlServer(@"Server=.\;Database=Northwind;Trusted_Connection=True;")
.UseMappingSchema(myFluentMappings);
var db = new DataConnection(option);
This approach involves no attributes at all. In this case Linq To DB will use POCO's name as table name and property names as column names (with exact same casing, which could be important for case-sensitive databases). This might seem to be convenient, but there are some restrictions:
- Linq To DB will not infer primary key even if class has property called
ID
; - it will not infer nullability of reference types if you don't use nullable reference types annotations;
- associations will not be automatically configured.
using System;
using LinqToDB.Mapping;
public class Product
{
public int ProductID { get; set; }
public string Name { get; set; }
public int VendorID { get; set; }
public Vendor Vendor { get; set; }
// ... other columns ...
}
This way Linq To DB will auto-configure Product
class to map to Product
table with fields ProductID
, Name
, and VendorID
. POCO will not get ProductID
property treated as primary key. And there will be no association with Vendor
.
This approach is not generally recommended.
At this point LINQ to DB doesn't know how to connect to our database or which POCOs go with what database. All this mapping is done through a DataConnection
class:
public class DbNorthwind : LinqToDB.Data.DataConnection
{
public DbNorthwind() : base("Northwind") { }
public ITable<Product> Product => this.GetTable<Product>();
public ITable<Category> Category => this.GetTable<Category>();
// ... other tables ...
}
We call the base constructor with the "Northwind" parameter. This parameter (called configuration name
) has to match the name="Northwind"
we defined above as name of our connection string. We also added convenience properties for Product
and Category
mapping classes to write LINQ queries.
And now let's get some data:
using LinqToDB;
using LinqToDB.Common;
public static List<Product> GetProducts()
{
using var db = new DbNorthwind();
var query = from p in db.Product
where p.ProductID > 25
orderby p.Name descending
select p;
return query.ToList();
}
Make sure you always wrap your DataConnection
class (in our case DbNorthwind
) in a using
statement. This is required for proper resource management, like releasing the database connections back into the pool (more details).
Most times we get the entire row from the database:
from p in db.Product
where p.ProductID == 5
select p;
However, sometimes getting all the fields is too wasteful so we want only certain fields, but still use our POCOs; something that is challenging for libraries that rely on object tracking, like LINQ to SQL.
from p in db.Product
orderby p.Name descending
select new Product
{
Name = p.Name
};
Rather than concatenating strings we can 'compose' LINQ expressions. In the example below the final SQL will be different if onlyActive
is true or false, or if searchFor
is not null.
public static Product[] GetProducts(bool onlyActive, string searchFor)
{
using var db = new DbNorthwind();
var products = from p in db.Product
select p;
if (onlyActive)
{
products = from p in products
where !p.Discontinued
select p;
}
if (searchFor != null)
{
products = from p in products
where p.Name.Contains(searchFor)
select p;
}
return products.ToArray();
}
A lot of times we need to write code that returns only a subset of the entire dataset. We expand on the previous example to show what a product search function could look like.
Keep in mind that the code below will query the database twice. Once to find out the total number of records, something that is required by many paging controls, and once to return the actual data.
public static List<Product> Search(
string searchFor,
int currentPage,
int pageSize,
out int totalRecords)
{
using var db = new DbNorthwind();
var products = from p in db.Product
select p;
if (searchFor != null)
{
products = from p in products
where p.Name.Contains(searchFor)
select p;
}
totalRecords = products.Count();
return products.Skip((currentPage - 1) * pageSize).Take(pageSize).ToList();
}
This assumes we added a Category
class, just like we did with the Product
class, defined all the fields, and defined table access property in our DbNorthwind
data access class. We can now write an INNER JOIN query like this:
from p in db.Product
join c in db.Category on p.CategoryID equals c.CategoryID
select new Product
{
Name = p.Name,
Category = c
};
and a LEFT JOIN query like this:
from p in db.Product
from c in db.Category.Where(q => q.CategoryID == p.CategoryID).DefaultIfEmpty()
select new Product
{
Name = p.Name,
Category = c
};
In the previous example we assign an entire Category
object to our product, but what if we want all the fields in our Product
class, but we don't want to specify every field by hand? Unfortunately, we cannot write this:
from p in db.Product
from c in db.Category.Where(q => q.CategoryID == p.CategoryID).DefaultIfEmpty()
select new Product(c);
The query above assumes the Product class has a constructor that takes in a Category
object. The query above won't work, but we can work around that with the following query:
from p in db.Product
from c in db.Category.Where(q => q.CategoryID == p.CategoryID).DefaultIfEmpty()
select Product.Build(p, c);
For this to work, we need a function in the Product
class that looks like this:
public static Product Build(Product? product, Category category)
{
if (product != null)
{
product.Category = category;
}
return product;
}
One caveat with this approach is that if you're using it with composed queries (see example above) the select Build
part has to come only in the final select.
At some point we will need to add a new Product
to the database. One way would be to call the Insert
extension method found in the LinqToDB
namespace; so make sure you import that.
using LinqToDB;
using var db = new DbNorthwind();
db.Insert(product);
This inserts all the columns from our Product
class, but without retrieving the generated identity value. To do that we can use InsertWith*Identity
methods, like this:
using LinqToDB;
using var db = new DbNorthwind();
product.ProductID = db.InsertWithInt32Identity(product);
There is also InsertOrReplace
that updates a database record if it was found by primary key or adds it otherwise.
If you need to insert only certain fields, or use values generated by the database, you could write:
using LinqToDB;
using var db = new DbNorthwind();
db.Product
.Value(p => p.Name, product.Name)
.Value(p => p.UnitPrice, 10.2m)
.Value(p => p.Added, () => Sql.CurrentTimestamp)
.Insert();
Use of this method also allows us to build insert statements like this:
using LinqToDB;
using var db = new DbNorthwind();
var statement = db.Product
.Value(p => p.Name, product.Name)
.Value(p => p.UnitPrice, 10.2m);
if (storeAdded) statement.Value(p => p.Added, () => Sql.CurrentTimestamp);
statement.Insert();
Updating records follows similar pattern to Insert
. We have an extension method that updates all the columns in the database:
using LinqToDB;
using var db = new DbNorthwind();
db.Update(product);
And we also have a lower level update mechanism:
using LinqToDB;
using var db = new DbNorthwind();
db.Product
.Where(p => p.ProductID == product.ProductID)
.Set(p => p.Name, product.Name)
.Set(p => p.UnitPrice, product.UnitPrice)
.Update();
Similarly, we can break an update query into multiple pieces if needed:
using LinqToDB;
using var db = new DbNorthwind();
var statement = db.Product
.Where(p => p.ProductID == product.ProductID)
.Set(p => p.Name, product.Name);
if (updatePrice) statement = statement.Set(p => p.UnitPrice, product.UnitPrice);
statement.Update();
You're not limited to a single record update. For example, we could discontinue all the products that are no longer in stock:
using LinqToDB;
using var db = new DbNorthwind();
db.Product
.Where(p => p.UnitsInStock == 0)
.Set(p => p.Discontinued, true)
.Update();
Similar to how you update records, you can also delete records:
using LinqToDB;
using var db = new DbNorthwind();
db.Product
.Where(p => p.Discontinued)
.Delete();
Bulk copy feature supports the transfer of large amounts of data into a table from another data source. For more details read this article.
using LinqToDB.Data;
[Table("ProductsTemp")]
public class ProductTemp
{
[PrimaryKey]
public int ProductID { get; set; }
[Column("ProductName"), NotNull]
public string Name { get; set; }
// ... other columns ...
}
var list = new List<ProductTemp>();
// ... populate list ...
using var db = new DbNorthwind();
db.BulkCopy(list);
Using database transactions is easy. All you have to do is call BeginTransaction()
on your DataConnection
, run one or more queries, and then commit the changes by calling CommitTransaction()
. If something happened and you need to roll back your changes you can either call RollbackTransaction()
or throw an exception.
using var db = new DbNorthwind();
db.BeginTransaction();
// or
//using var tr = db.BeginTransaction();
// ... select / insert / update / delete ...
if (somethingIsNotRight)
{
db.RollbackTransaction();
// or
// tr.Rollback();
}
else
{
db.CommitTransaction();
// or
// tr.Commit();
}
Also, you can use .NET built-in TransactionScope
class:
using var transaction = new TransactionScope();
// or for async code
// using var transaction = new TransactionScope(TransactionScopeAsyncFlowOption.Enabled);
using var db = new DbNorthwind();
...
transaction.Complete();
It should be noted that there are two base classes for your "context" class: LinqToDB.Data.DataConnection
and LinqToDB.DataContext
. The key difference between them is in connection retention behaviour. DataConnection
opens connection with first query and holds it open until dispose happens. DataContext
behaves the way you might used to with Entity Framework: it opens connection per query and closes it right after query is done.
This difference in behavior matters when used with TransactionScope
:
using var db = new LinqToDB.Data.DataConnection("provider name", "connection string");
var product = db.GetTable<Product>()
.FirstOrDefault(); // connection opened here
var scope = new TransactionScope();
// this transaction was not attached to connection
// because it was opened earlier
product.Name = "Lollipop";
db.Update(product);
scope.Dispose();
// no transaction rollback happed, "Lollipop" has been saved
A DataConnection
is attached with ambient transaction in moment it is opened. Any TransactionScope
s created after the connection is created will no effect on that connection. Replacing DataConnection
with DataContext
in code shown earlier will make transaction scope work as expected: the created record will be discarded with the transaction.
Although, DataContext
appears to be the right class to choose, it is strongly recommended to use DataConnection
instead. It's default behaviour might be changed with setting CloseAfterUse
property to true
:
public class DbNorthwind : LinqToDB.Data.DataConnection
{
public DbNorthwind() : base("Northwind")
{
(this as IDataContext).CloseAfterUse = true;
}
}
Here you can read about SQL MERGE support.
Here you can read about Window (Analytic) Functions support.
If you would like to use MiniProfiler or other profiling tool that wraps ADO.NET provider classes, you need to configure our regular DataConnection
to use wrapped connection.
// example of SQL Server-backed data connection with MiniProfiler enabled for debug builds
public class DbDataContext : DataConnection
{
// let's use profiler only for debug builds
#if !DEBUG
// regular non-profiled constructor
public DbDataContext() : base("Northwind") {}
#else
public DbDataContext()
: base(
new DataOptions()
.UseSqlServer(connectionString, SqlServerVersion.v2012)
.UseConnectionFactory(GetConnection)
.UseInterceptor(new UnwrapProfilerInterceptor()))
{
}
// wrap connection into profiler wrapper
private static DbConnection GetConnection(DataOptions options)
{
// create provider-specific connection instance. SqlConnection in our case
var dbConnection = new SqlConnection(options.ConnectionOptions.ConnectionString);
// wrap it by profiler's connection implementation
return new StackExchange.Profiling.Data.ProfiledDbConnection(
dbConnection,
MiniProfiler.Current);
}
// define UnwrapDataObjectInterceptor
sealed class UnwrapProfilerInterceptor : UnwrapDataObjectInterceptor
{
public override DbConnection UnwrapConnection(IDataContext dataContext, DbConnection connection)
{
return connection is ProfiledDbConnection c ? c.WrappedConnection : connection;
}
public override DbTransaction UnwrapTransaction(IDataContext dataContext, DbTransaction transaction)
{
return transaction is ProfiledDbTransaction t ? t.WrappedTransaction : transaction;
}
public override DbCommand UnwrapCommand(IDataContext dataContext, DbCommand command)
{
return command is ProfiledDbCommand c ? c.WrappedCommand : command;
}
public override DbDataReader UnwrapDataReader(IDataContext dataContext, DbDataReader dataReader)
{
return dataReader is ProfiledDbDataReader dr ? dr.WrappedReader : dataReader;
}
}
#endif
}
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